/******************************************************************************
 *
 * Project:  CIETMap Phase 2
 * Purpose:  Convert RGB (24bit) to a pseudo-colored approximation using
 *           Floyd-Steinberg dithering (error diffusion).
 * Author:   Frank Warmerdam, warmerdam@pobox.com
 *
 ******************************************************************************
 * Copyright (c) 2001, Frank Warmerdam
 * Copyright (c) 2007, Even Rouault <even dot rouault at spatialys.com>
 *
 * SPDX-License-Identifier: MIT
 ******************************************************************************
 *
 * Notes:
 *
 * [1] Floyd-Steinberg dither:
 *  I should point out that the actual fractions we used were, assuming
 *  you are at X, moving left to right:
 *
 *                    X     7/16
 *             3/16   5/16  1/16
 *
 *  Note that the error goes to four neighbors, not three.  I think this
 *  will probably do better (at least for black and white) than the
 *  3/8-3/8-1/4 distribution, at the cost of greater processing.  I have
 *  seen the 3/8-3/8-1/4 distribution described as "our" algorithm before,
 *  but I have no idea who the credit really belongs to.
 *  --
 *                                          Lou Steinberg
 */

#include "cpl_port.h"
#include "gdal_alg.h"
#include "gdal_alg_priv.h"

#include <cstdlib>
#include <cstring>
#include <algorithm>

#include "cpl_conv.h"
#include "cpl_error.h"
#include "cpl_progress.h"
#include "cpl_vsi.h"
#include "gdal.h"
#include "gdal_priv.h"

#ifdef USE_NEON_OPTIMIZATIONS
#define USE_SSE2
#include "include_sse2neon.h"
#elif defined(__x86_64) || defined(_M_X64)
#define USE_SSE2
#include <emmintrin.h>
#endif

#ifdef USE_SSE2

#define CAST_PCT(x) reinterpret_cast<GByte *>(x)
#define ALIGN_INT_ARRAY_ON_16_BYTE(x)                                          \
    (((reinterpret_cast<GUIntptr_t>(x) % 16) != 0)                             \
         ? reinterpret_cast<int *>(reinterpret_cast<GByte *>(x) + 16 -         \
                                   (reinterpret_cast<GUIntptr_t>(x) % 16))     \
         : (x))
#else
#define CAST_PCT(x) x
#endif

#ifndef MAKE_COLOR_CODE_defined
#define MAKE_COLOR_CODE_defined

static int MAKE_COLOR_CODE(int r, int g, int b)
{
    return r | (g << 8) | (b << 16);
}
#endif

static void FindNearestColor(int nColors, int *panPCT, GByte *pabyColorMap,
                             int nCLevels);
static int FindNearestColor(int nColors, int *panPCT, int nRedValue,
                            int nGreenValue, int nBlueValue);

// Structure for a hashmap from a color code to a color index of the
// color table.

// NOTE: if changing the size of this structure, edit
// MEDIAN_CUT_AND_DITHER_BUFFER_SIZE_65536 in gdal_alg_priv.h and take
// into account HashHistogram in gdalmediancut.cpp.
typedef struct
{
    GUInt32 nColorCode;
    GUInt32 nColorCode2;
    GUInt32 nColorCode3;
    GByte nIndex;
    GByte nIndex2;
    GByte nIndex3;
    GByte nPadding;
} ColorIndex;

/************************************************************************/
/*                         GDALDitherRGB2PCT()                          */
/************************************************************************/

#ifndef IsColorCodeSet_defined
#define IsColorCodeSet_defined

static inline bool IsColorCodeSet(GUInt32 nColorCode)
{
    return (nColorCode >> 31) == 0;
}
#endif

/**
 * 24bit to 8bit conversion with dithering.
 *
 * This functions utilizes Floyd-Steinberg dithering in the process of
 * converting a 24bit RGB image into a pseudocolored 8bit image using a
 * provided color table.
 *
 * The red, green and blue input bands do not necessarily need to come
 * from the same file, but they must be the same width and height.  They will
 * be clipped to 8bit during reading, so non-eight bit bands are generally
 * inappropriate.  Likewise the hTarget band will be written with 8bit values
 * and must match the width and height of the source bands.
 *
 * The color table cannot have more than 256 entries.
 *
 * @param hRed Red input band.
 * @param hGreen Green input band.
 * @param hBlue Blue input band.
 * @param hTarget Output band.
 * @param hColorTable the color table to use with the output band.
 * @param pfnProgress callback for reporting algorithm progress matching the
 * GDALProgressFunc() semantics.  May be NULL.
 * @param pProgressArg callback argument passed to pfnProgress.
 *
 * @return CE_None on success or CE_Failure if an error occurs.
 */

int CPL_STDCALL GDALDitherRGB2PCT(GDALRasterBandH hRed, GDALRasterBandH hGreen,
                                  GDALRasterBandH hBlue,
                                  GDALRasterBandH hTarget,
                                  GDALColorTableH hColorTable,
                                  GDALProgressFunc pfnProgress,
                                  void *pProgressArg)

{
    return GDALDitherRGB2PCTInternal(hRed, hGreen, hBlue, hTarget, hColorTable,
                                     5, nullptr, TRUE, pfnProgress,
                                     pProgressArg);
}

int GDALDitherRGB2PCTInternal(
    GDALRasterBandH hRed, GDALRasterBandH hGreen, GDALRasterBandH hBlue,
    GDALRasterBandH hTarget, GDALColorTableH hColorTable, int nBits,
    // NULL or at least 256 * 256 * 256 * sizeof(GInt16) bytes.
    GInt16 *pasDynamicColorMap, int bDither, GDALProgressFunc pfnProgress,
    void *pProgressArg)
{
    VALIDATE_POINTER1(hRed, "GDALDitherRGB2PCT", CE_Failure);
    VALIDATE_POINTER1(hGreen, "GDALDitherRGB2PCT", CE_Failure);
    VALIDATE_POINTER1(hBlue, "GDALDitherRGB2PCT", CE_Failure);
    VALIDATE_POINTER1(hTarget, "GDALDitherRGB2PCT", CE_Failure);
    VALIDATE_POINTER1(hColorTable, "GDALDitherRGB2PCT", CE_Failure);

    /* -------------------------------------------------------------------- */
    /*      Validate parameters.                                            */
    /* -------------------------------------------------------------------- */
    const int nXSize = GDALGetRasterBandXSize(hRed);
    const int nYSize = GDALGetRasterBandYSize(hRed);

    if (GDALGetRasterBandXSize(hGreen) != nXSize ||
        GDALGetRasterBandYSize(hGreen) != nYSize ||
        GDALGetRasterBandXSize(hBlue) != nXSize ||
        GDALGetRasterBandYSize(hBlue) != nYSize)
    {
        CPLError(CE_Failure, CPLE_IllegalArg,
                 "Green or blue band doesn't match size of red band.");

        return CE_Failure;
    }

    if (GDALGetRasterBandXSize(hTarget) != nXSize ||
        GDALGetRasterBandYSize(hTarget) != nYSize)
    {
        CPLError(CE_Failure, CPLE_IllegalArg,
                 "GDALDitherRGB2PCT(): "
                 "Target band doesn't match size of source bands.");

        return CE_Failure;
    }

    if (pfnProgress == nullptr)
        pfnProgress = GDALDummyProgress;

    /* -------------------------------------------------------------------- */
    /*      Setup more direct colormap.                                     */
    /* -------------------------------------------------------------------- */
    int iColor;
#ifdef USE_SSE2
    int anPCTUnaligned[256 + 4];  // 4 for alignment on 16-byte boundary.
    int *anPCT = ALIGN_INT_ARRAY_ON_16_BYTE(anPCTUnaligned);
#else
    int anPCT[256 * 4] = {};
#endif
    const int nColors = GDALGetColorEntryCount(hColorTable);

    if (nColors == 0)
    {
        CPLError(CE_Failure, CPLE_IllegalArg,
                 "GDALDitherRGB2PCT(): "
                 "Color table must not be empty.");

        return CE_Failure;
    }
    else if (nColors > 256)
    {
        CPLError(CE_Failure, CPLE_IllegalArg,
                 "GDALDitherRGB2PCT(): "
                 "Color table cannot have more than 256 entries.");

        return CE_Failure;
    }

    iColor = 0;
    do
    {
        GDALColorEntry sEntry;

        GDALGetColorEntryAsRGB(hColorTable, iColor, &sEntry);
        CAST_PCT(anPCT)[4 * iColor + 0] = static_cast<GByte>(sEntry.c1);
        CAST_PCT(anPCT)[4 * iColor + 1] = static_cast<GByte>(sEntry.c2);
        CAST_PCT(anPCT)[4 * iColor + 2] = static_cast<GByte>(sEntry.c3);
        CAST_PCT(anPCT)[4 * iColor + 3] = 0;

        iColor++;
    } while (iColor < nColors);

#ifdef USE_SSE2
    // Pad to multiple of 8 colors.
    const int nColorsMod8 = nColors % 8;
    if (nColorsMod8)
    {
        int iDest = nColors;
        for (iColor = 0; iColor < 8 - nColorsMod8 && iDest < 256;
             iColor++, iDest++)
        {
            anPCT[iDest] = anPCT[nColors - 1];
        }
    }
#endif

    /* -------------------------------------------------------------------- */
    /*      Setup various variables.                                        */
    /* -------------------------------------------------------------------- */
    const int nCLevels = 1 << nBits;
    const int nCLevelsCube = nCLevels * nCLevels * nCLevels;
    ColorIndex *psColorIndexMap = nullptr;

    GByte *pabyRed = static_cast<GByte *>(VSI_MALLOC_VERBOSE(nXSize));
    GByte *pabyGreen = static_cast<GByte *>(VSI_MALLOC_VERBOSE(nXSize));
    GByte *pabyBlue = static_cast<GByte *>(VSI_MALLOC_VERBOSE(nXSize));

    GByte *pabyIndex = static_cast<GByte *>(VSI_MALLOC_VERBOSE(nXSize));

    int *panError =
        static_cast<int *>(VSI_CALLOC_VERBOSE(sizeof(int), (nXSize + 2) * 3));

    if (pabyRed == nullptr || pabyGreen == nullptr || pabyBlue == nullptr ||
        pabyIndex == nullptr || panError == nullptr)
    {
        CPLFree(pabyRed);
        CPLFree(pabyGreen);
        CPLFree(pabyBlue);
        CPLFree(pabyIndex);
        CPLFree(panError);

        return CE_Failure;
    }

    GByte *pabyColorMap = nullptr;
    if (pasDynamicColorMap == nullptr)
    {
        /* --------------------------------------------------------------------
         */
        /*      Build a 24bit to 8 bit color mapping. */
        /* --------------------------------------------------------------------
         */

        pabyColorMap = static_cast<GByte *>(
            VSI_MALLOC_VERBOSE(nCLevelsCube * sizeof(GByte)));
        if (pabyColorMap == nullptr)
        {
            CPLFree(pabyRed);
            CPLFree(pabyGreen);
            CPLFree(pabyBlue);
            CPLFree(pabyIndex);
            CPLFree(panError);
            CPLFree(pabyColorMap);

            return CE_Failure;
        }

        FindNearestColor(nColors, anPCT, pabyColorMap, nCLevels);
    }
    else
    {
        pabyColorMap = nullptr;
        if (nBits == 8 && static_cast<GIntBig>(nXSize) * nYSize <= 65536)
        {
            // If the image is small enough, then the number of colors
            // will be limited and using a hashmap, rather than a full table
            // will be more efficient.
            psColorIndexMap =
                reinterpret_cast<ColorIndex *>(pasDynamicColorMap);
            memset(psColorIndexMap, 0xFF, sizeof(ColorIndex) * PRIME_FOR_65536);
        }
        else
        {
            memset(pasDynamicColorMap, 0xFF, 256 * 256 * 256 * sizeof(GInt16));
        }
    }

    /* ==================================================================== */
    /*      Loop over all scanlines of data to process.                     */
    /* ==================================================================== */
    CPLErr err = CE_None;

    for (int iScanline = 0; iScanline < nYSize; iScanline++)
    {
        /* --------------------------------------------------------------------
         */
        /*      Report progress */
        /* --------------------------------------------------------------------
         */
        if (!pfnProgress(iScanline / static_cast<double>(nYSize), nullptr,
                         pProgressArg))
        {
            CPLError(CE_Failure, CPLE_UserInterrupt, "User Terminated");
            CPLFree(pabyRed);
            CPLFree(pabyGreen);
            CPLFree(pabyBlue);
            CPLFree(pabyIndex);
            CPLFree(panError);
            CPLFree(pabyColorMap);

            return CE_Failure;
        }

        /* --------------------------------------------------------------------
         */
        /*      Read source data. */
        /* --------------------------------------------------------------------
         */
        CPLErr err1 = GDALRasterIO(hRed, GF_Read, 0, iScanline, nXSize, 1,
                                   pabyRed, nXSize, 1, GDT_Byte, 0, 0);
        if (err1 == CE_None)
            err1 = GDALRasterIO(hGreen, GF_Read, 0, iScanline, nXSize, 1,
                                pabyGreen, nXSize, 1, GDT_Byte, 0, 0);
        if (err1 == CE_None)
            err1 = GDALRasterIO(hBlue, GF_Read, 0, iScanline, nXSize, 1,
                                pabyBlue, nXSize, 1, GDT_Byte, 0, 0);
        if (err1 != CE_None)
        {
            CPLFree(pabyRed);
            CPLFree(pabyGreen);
            CPLFree(pabyBlue);
            CPLFree(pabyIndex);
            CPLFree(panError);
            CPLFree(pabyColorMap);

            return err1;
        }

        /* --------------------------------------------------------------------
         */
        /*      Apply the error from the previous line to this one. */
        /* --------------------------------------------------------------------
         */
        if (bDither)
        {
            for (int i = 0; i < nXSize; i++)
            {
                pabyRed[i] = static_cast<GByte>(std::max(
                    0, std::min(255, (pabyRed[i] + panError[i * 3 + 0 + 3]))));
                pabyGreen[i] = static_cast<GByte>(std::max(
                    0,
                    std::min(255, (pabyGreen[i] + panError[i * 3 + 1 + 3]))));
                pabyBlue[i] = static_cast<GByte>(std::max(
                    0, std::min(255, (pabyBlue[i] + panError[i * 3 + 2 + 3]))));
            }

            memset(panError, 0, sizeof(int) * (nXSize + 2) * 3);
        }

        /* --------------------------------------------------------------------
         */
        /*      Figure out the nearest color to the RGB value. */
        /* --------------------------------------------------------------------
         */
        int nLastRedError = 0;
        int nLastGreenError = 0;
        int nLastBlueError = 0;

        for (int i = 0; i < nXSize; i++)
        {
            const int nRedValue =
                std::max(0, std::min(255, pabyRed[i] + nLastRedError));
            const int nGreenValue =
                std::max(0, std::min(255, pabyGreen[i] + nLastGreenError));
            const int nBlueValue =
                std::max(0, std::min(255, pabyBlue[i] + nLastBlueError));

            int iIndex = 0;
            int nError = 0;
            int nSixth = 0;
            if (psColorIndexMap)
            {
                const GUInt32 nColorCode =
                    MAKE_COLOR_CODE(nRedValue, nGreenValue, nBlueValue);
                GUInt32 nIdx = nColorCode % PRIME_FOR_65536;
                while (true)
                {
                    if (psColorIndexMap[nIdx].nColorCode == nColorCode)
                    {
                        iIndex = psColorIndexMap[nIdx].nIndex;
                        break;
                    }
                    if (!IsColorCodeSet(psColorIndexMap[nIdx].nColorCode))
                    {
                        psColorIndexMap[nIdx].nColorCode = nColorCode;
                        iIndex = FindNearestColor(nColors, anPCT, nRedValue,
                                                  nGreenValue, nBlueValue);
                        psColorIndexMap[nIdx].nIndex =
                            static_cast<GByte>(iIndex);
                        break;
                    }
                    if (psColorIndexMap[nIdx].nColorCode2 == nColorCode)
                    {
                        iIndex = psColorIndexMap[nIdx].nIndex2;
                        break;
                    }
                    if (!IsColorCodeSet(psColorIndexMap[nIdx].nColorCode2))
                    {
                        psColorIndexMap[nIdx].nColorCode2 = nColorCode;
                        iIndex = FindNearestColor(nColors, anPCT, nRedValue,
                                                  nGreenValue, nBlueValue);
                        psColorIndexMap[nIdx].nIndex2 =
                            static_cast<GByte>(iIndex);
                        break;
                    }
                    if (psColorIndexMap[nIdx].nColorCode3 == nColorCode)
                    {
                        iIndex = psColorIndexMap[nIdx].nIndex3;
                        break;
                    }
                    if (!IsColorCodeSet(psColorIndexMap[nIdx].nColorCode3))
                    {
                        psColorIndexMap[nIdx].nColorCode3 = nColorCode;
                        iIndex = FindNearestColor(nColors, anPCT, nRedValue,
                                                  nGreenValue, nBlueValue);
                        psColorIndexMap[nIdx].nIndex3 =
                            static_cast<GByte>(iIndex);
                        break;
                    }

                    do
                    {
                        nIdx += 257;
                        if (nIdx >= PRIME_FOR_65536)
                            nIdx -= PRIME_FOR_65536;
                    } while (
                        IsColorCodeSet(psColorIndexMap[nIdx].nColorCode) &&
                        psColorIndexMap[nIdx].nColorCode != nColorCode &&
                        IsColorCodeSet(psColorIndexMap[nIdx].nColorCode2) &&
                        psColorIndexMap[nIdx].nColorCode2 != nColorCode &&
                        IsColorCodeSet(psColorIndexMap[nIdx].nColorCode3) &&
                        psColorIndexMap[nIdx].nColorCode3 != nColorCode);
                }
            }
            else if (pasDynamicColorMap == nullptr)
            {
                const int iRed = nRedValue * nCLevels / 256;
                const int iGreen = nGreenValue * nCLevels / 256;
                const int iBlue = nBlueValue * nCLevels / 256;

                iIndex = pabyColorMap[iRed + iGreen * nCLevels +
                                      iBlue * nCLevels * nCLevels];
            }
            else
            {
                const GUInt32 nColorCode =
                    MAKE_COLOR_CODE(nRedValue, nGreenValue, nBlueValue);
                GInt16 *psIndex = &pasDynamicColorMap[nColorCode];
                if (*psIndex < 0)
                {
                    *psIndex = static_cast<GInt16>(FindNearestColor(
                        nColors, anPCT, nRedValue, nGreenValue, nBlueValue));
                    iIndex = *psIndex;
                }
                else
                {
                    iIndex = *psIndex;
                }
            }

            pabyIndex[i] = static_cast<GByte>(iIndex);
            if (!bDither)
                continue;

            /* --------------------------------------------------------------------
             */
            /*      Compute Red error, and carry it on to the next error line.
             */
            /* --------------------------------------------------------------------
             */
            nError = nRedValue - CAST_PCT(anPCT)[4 * iIndex + 0];
            nSixth = nError / 6;

            panError[i * 3] += nSixth;
            panError[i * 3 + 6] = nSixth;
            panError[i * 3 + 3] += nError - 5 * nSixth;

            nLastRedError = 2 * nSixth;

            /* --------------------------------------------------------------------
             */
            /*      Compute Green error, and carry it on to the next error line.
             */
            /* --------------------------------------------------------------------
             */
            nError = nGreenValue - CAST_PCT(anPCT)[4 * iIndex + 1];
            nSixth = nError / 6;

            panError[i * 3 + 1] += nSixth;
            panError[i * 3 + 6 + 1] = nSixth;
            panError[i * 3 + 3 + 1] += nError - 5 * nSixth;

            nLastGreenError = 2 * nSixth;

            /* --------------------------------------------------------------------
             */
            /*      Compute Blue error, and carry it on to the next error line.
             */
            /* --------------------------------------------------------------------
             */
            nError = nBlueValue - CAST_PCT(anPCT)[4 * iIndex + 2];
            nSixth = nError / 6;

            panError[i * 3 + 2] += nSixth;
            panError[i * 3 + 6 + 2] = nSixth;
            panError[i * 3 + 3 + 2] += nError - 5 * nSixth;

            nLastBlueError = 2 * nSixth;
        }

        /* --------------------------------------------------------------------
         */
        /*      Write results. */
        /* --------------------------------------------------------------------
         */
        err = GDALRasterIO(hTarget, GF_Write, 0, iScanline, nXSize, 1,
                           pabyIndex, nXSize, 1, GDT_Byte, 0, 0);
        if (err != CE_None)
            break;
    }

    pfnProgress(1.0, nullptr, pProgressArg);

    /* -------------------------------------------------------------------- */
    /*      Cleanup                                                         */
    /* -------------------------------------------------------------------- */
    CPLFree(pabyRed);
    CPLFree(pabyGreen);
    CPLFree(pabyBlue);
    CPLFree(pabyIndex);
    CPLFree(panError);
    CPLFree(pabyColorMap);

    return err;
}

static int FindNearestColor(int nColors, int *panPCT, int nRedValue,
                            int nGreenValue, int nBlueValue)

{
#ifdef USE_SSE2
    int nBestDist = 768;
    int nBestIndex = 0;

    int anDistanceUnaligned[16 + 4] =
        {};  // 4 for alignment on 16-byte boundary.
    int *anDistance = ALIGN_INT_ARRAY_ON_16_BYTE(anDistanceUnaligned);

    const __m128i ff = _mm_set1_epi32(0xFFFFFFFF);
    const __m128i mask_low = _mm_srli_epi64(ff, 32);
    const __m128i mask_high = _mm_slli_epi64(ff, 32);

    const unsigned int nColorVal =
        MAKE_COLOR_CODE(nRedValue, nGreenValue, nBlueValue);
    const __m128i thisColor = _mm_set1_epi32(nColorVal);
    const __m128i thisColor_low = _mm_srli_epi64(thisColor, 32);
    const __m128i thisColor_high = _mm_slli_epi64(thisColor, 32);

    for (int iColor = 0; iColor < nColors; iColor += 8)
    {
        const __m128i pctColor =
            _mm_load_si128(reinterpret_cast<__m128i *>(&panPCT[iColor]));
        const __m128i pctColor2 =
            _mm_load_si128(reinterpret_cast<__m128i *>(&panPCT[iColor + 4]));

        _mm_store_si128(
            reinterpret_cast<__m128i *>(anDistance),
            _mm_sad_epu8(_mm_and_si128(pctColor, mask_low), thisColor_low));
        _mm_store_si128(
            reinterpret_cast<__m128i *>(anDistance + 4),
            _mm_sad_epu8(_mm_and_si128(pctColor, mask_high), thisColor_high));
        _mm_store_si128(
            reinterpret_cast<__m128i *>(anDistance + 8),
            _mm_sad_epu8(_mm_and_si128(pctColor2, mask_low), thisColor_low));
        _mm_store_si128(
            reinterpret_cast<__m128i *>(anDistance + 12),
            _mm_sad_epu8(_mm_and_si128(pctColor2, mask_high), thisColor_high));

        if (anDistance[0] < nBestDist)
        {
            nBestIndex = iColor;
            nBestDist = anDistance[0];
        }
        if (anDistance[4] < nBestDist)
        {
            nBestIndex = iColor + 1;
            nBestDist = anDistance[4];
        }
        if (anDistance[2] < nBestDist)
        {
            nBestIndex = iColor + 2;
            nBestDist = anDistance[2];
        }
        if (anDistance[6] < nBestDist)
        {
            nBestIndex = iColor + 3;
            nBestDist = anDistance[6];
        }
        if (anDistance[8 + 0] < nBestDist)
        {
            nBestIndex = iColor + 4;
            nBestDist = anDistance[8 + 0];
        }
        if (anDistance[8 + 4] < nBestDist)
        {
            nBestIndex = iColor + 4 + 1;
            nBestDist = anDistance[8 + 4];
        }
        if (anDistance[8 + 2] < nBestDist)
        {
            nBestIndex = iColor + 4 + 2;
            nBestDist = anDistance[8 + 2];
        }
        if (anDistance[8 + 6] < nBestDist)
        {
            nBestIndex = iColor + 4 + 3;
            nBestDist = anDistance[8 + 6];
        }
    }
    return nBestIndex;
#else
    int nBestDist = 768;
    int nBestIndex = 0;

    for (int iColor = 0; iColor < nColors; iColor++)
    {
        const int nThisDist = std::abs(nRedValue - panPCT[4 * iColor + 0]) +
                              std::abs(nGreenValue - panPCT[4 * iColor + 1]) +
                              std::abs(nBlueValue - panPCT[4 * iColor + 2]);

        if (nThisDist < nBestDist)
        {
            nBestIndex = iColor;
            nBestDist = nThisDist;
        }
    }
    return nBestIndex;
#endif
}

/************************************************************************/
/*                          FindNearestColor()                          */
/*                                                                      */
/*      Finear near PCT color for any RGB color.                        */
/************************************************************************/

static void FindNearestColor(int nColors, int *panPCT, GByte *pabyColorMap,
                             int nCLevels)

{
    /* -------------------------------------------------------------------- */
    /*  Loop over all the cells in the high density cube.                   */
    /* -------------------------------------------------------------------- */
    for (int iBlue = 0; iBlue < nCLevels; iBlue++)
    {
        for (int iGreen = 0; iGreen < nCLevels; iGreen++)
        {
            for (int iRed = 0; iRed < nCLevels; iRed++)
            {
                const int nRedValue = (iRed * 255) / (nCLevels - 1);
                const int nGreenValue = (iGreen * 255) / (nCLevels - 1);
                const int nBlueValue = (iBlue * 255) / (nCLevels - 1);

                const int nBestIndex = FindNearestColor(
                    nColors, panPCT, nRedValue, nGreenValue, nBlueValue);
                pabyColorMap[iRed + iGreen * nCLevels +
                             iBlue * nCLevels * nCLevels] =
                    static_cast<GByte>(nBestIndex);
            }
        }
    }
}
